mirror of
https://github.com/espressif/esp-idf.git
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90d1dcfd76
This commit replaces the use of portNUM_PROCESSORS and configNUM_CORES macros in all of ESP-IDF. These macros are needed to realize an SMP scenario by fetching the number of active cores FreeRTOS is running on. Instead, a new Kconfig option, CONFIG_FREERTOS_NUMBER_OF_CORES, has been added as a proxy for the FreeRTOS config option, configNUMBER_OF_CORES. This new commit is now used to realize an SMP scenario in various places in ESP-IDF. [Sudeep Mohanty: Added new Kconfig option CONFIG_FREERTOS_NUMBER_OF_CORES] Signed-off-by: Sudeep Mohanty <sudeep.mohanty@espressif.com>
203 lines
7.4 KiB
C
203 lines
7.4 KiB
C
/*
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* SPDX-FileCopyrightText: 2015-2024 Espressif Systems (Shanghai) CO LTD
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#include "sdkconfig.h"
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#include <stddef.h>
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#include <stdlib.h>
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#include <string.h>
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#include <assert.h>
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#include "esp_err.h"
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#include "esp_ipc.h"
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#include "esp_private/esp_ipc_isr.h"
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#include "esp_attr.h"
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#include "freertos/FreeRTOS.h"
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#include "freertos/task.h"
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#include "freertos/semphr.h"
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#if !defined(CONFIG_FREERTOS_UNICORE) || defined(CONFIG_APPTRACE_GCOV_ENABLE)
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#if CONFIG_COMPILER_OPTIMIZATION_NONE
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#define IPC_STACK_SIZE (CONFIG_ESP_IPC_TASK_STACK_SIZE + 0x100)
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#else
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#define IPC_STACK_SIZE (CONFIG_ESP_IPC_TASK_STACK_SIZE)
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#endif //CONFIG_COMPILER_OPTIMIZATION_NONE
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static DRAM_ATTR StaticSemaphore_t s_ipc_mutex_buffer[CONFIG_FREERTOS_NUMBER_OF_CORES];
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static DRAM_ATTR StaticSemaphore_t s_ipc_ack_buffer[CONFIG_FREERTOS_NUMBER_OF_CORES];
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static TaskHandle_t s_ipc_task_handle[CONFIG_FREERTOS_NUMBER_OF_CORES];
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static SemaphoreHandle_t s_ipc_mutex[CONFIG_FREERTOS_NUMBER_OF_CORES]; // This mutex is used as a global lock for esp_ipc_* APIs
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static SemaphoreHandle_t s_ipc_ack[CONFIG_FREERTOS_NUMBER_OF_CORES]; // Semaphore used to acknowledge that task was woken up,
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static volatile esp_ipc_func_t s_func[CONFIG_FREERTOS_NUMBER_OF_CORES] = { 0 }; // Function which should be called by high priority task
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static void * volatile s_func_arg[CONFIG_FREERTOS_NUMBER_OF_CORES]; // Argument to pass into s_func
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typedef enum {
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IPC_WAIT_NO = 0,
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IPC_WAIT_FOR_START,
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IPC_WAIT_FOR_END,
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} esp_ipc_wait_t;
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#if CONFIG_APPTRACE_GCOV_ENABLE
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static volatile esp_ipc_func_t s_gcov_func = NULL; // Gcov dump starter function which should be called by high priority task
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static void * volatile s_gcov_func_arg; // Argument to pass into s_gcov_func
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#endif
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static void IRAM_ATTR ipc_task(void* arg)
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{
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const int cpuid = (int) arg;
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assert(cpuid == xPortGetCoreID());
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#ifdef CONFIG_ESP_IPC_ISR_ENABLE
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esp_ipc_isr_init();
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#endif
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while (true) {
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uint32_t ipc_wait;
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xTaskNotifyWait(0, ULONG_MAX, &ipc_wait, portMAX_DELAY);
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#if CONFIG_APPTRACE_GCOV_ENABLE
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if (s_gcov_func) {
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(*s_gcov_func)(s_gcov_func_arg);
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s_gcov_func = NULL;
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/* we can not interfer with IPC calls so no need for further processing */
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// esp_ipc API and gcov_from_isr APIs can be processed together if they came at the same time
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if (ipc_wait == IPC_WAIT_NO) {
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continue;
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}
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}
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#endif // CONFIG_APPTRACE_GCOV_ENABLE
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#ifndef CONFIG_FREERTOS_UNICORE
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if (s_func[cpuid]) {
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// we need to cache s_func, s_func_arg and ipc_ack variables locally
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// because they can be changed by a subsequent IPC call (after xTaskNotify(caller_task_handle)).
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esp_ipc_func_t func = s_func[cpuid];
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s_func[cpuid] = NULL;
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void* func_arg = s_func_arg[cpuid];
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SemaphoreHandle_t ipc_ack = s_ipc_ack[cpuid];
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if (ipc_wait == IPC_WAIT_FOR_START) {
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xSemaphoreGive(ipc_ack);
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(*func)(func_arg);
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} else if (ipc_wait == IPC_WAIT_FOR_END) {
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(*func)(func_arg);
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xSemaphoreGive(ipc_ack);
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} else {
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abort();
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}
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}
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#endif // !CONFIG_FREERTOS_UNICORE
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}
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// TODO: currently this is unreachable code. Introduce esp_ipc_uninit
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// function which will signal to both tasks that they can shut down.
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// Not critical at this point, we don't have a use case for stopping
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// IPC yet.
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// Also need to delete the semaphore here.
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vTaskDelete(NULL);
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}
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/*
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* Initialize inter-processor call module. This function is called automatically
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* on CPU start and should not be called from the application.
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*
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* This function start two tasks, one on each CPU. These tasks are started
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* with high priority. These tasks are normally inactive, waiting until one of
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* the esp_ipc_call_* functions to be used. One of these tasks will be
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* woken up to execute the callback provided to esp_ipc_call_nonblocking or
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* esp_ipc_call_blocking.
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*/
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static void esp_ipc_init(void) __attribute__((constructor));
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static void esp_ipc_init(void)
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{
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char task_name[] = "ipcX"; // up to 10 ipc tasks/cores (0-9)
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for (int i = 0; i < CONFIG_FREERTOS_NUMBER_OF_CORES; ++i) {
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task_name[3] = i + (char)'0';
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s_ipc_mutex[i] = xSemaphoreCreateMutexStatic(&s_ipc_mutex_buffer[i]);
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s_ipc_ack[i] = xSemaphoreCreateBinaryStatic(&s_ipc_ack_buffer[i]);
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BaseType_t res = xTaskCreatePinnedToCore(ipc_task, task_name, IPC_STACK_SIZE, (void*) i,
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configMAX_PRIORITIES - 1, &s_ipc_task_handle[i], i);
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assert(res == pdTRUE);
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(void)res;
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}
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}
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static esp_err_t esp_ipc_call_and_wait(uint32_t cpu_id, esp_ipc_func_t func, void* arg, esp_ipc_wait_t wait_for)
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{
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if (cpu_id >= CONFIG_FREERTOS_NUMBER_OF_CORES) {
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return ESP_ERR_INVALID_ARG;
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}
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if (s_ipc_task_handle[cpu_id] == NULL) {
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return ESP_ERR_INVALID_STATE;
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}
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if (xTaskGetSchedulerState() != taskSCHEDULER_RUNNING) {
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return ESP_ERR_INVALID_STATE;
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}
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#ifdef CONFIG_ESP_IPC_USES_CALLERS_PRIORITY
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TaskHandle_t task_handler = xTaskGetCurrentTaskHandle();
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UBaseType_t priority_of_current_task = uxTaskPriorityGet(task_handler);
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UBaseType_t priority_of_running_ipc_task = uxTaskPriorityGet(s_ipc_task_handle[cpu_id]);
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if (priority_of_running_ipc_task < priority_of_current_task) {
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vTaskPrioritySet(s_ipc_task_handle[cpu_id], priority_of_current_task);
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}
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xSemaphoreTake(s_ipc_mutex[cpu_id], portMAX_DELAY);
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vTaskPrioritySet(s_ipc_task_handle[cpu_id], priority_of_current_task);
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#else
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xSemaphoreTake(s_ipc_mutex[0], portMAX_DELAY);
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#endif
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s_func[cpu_id] = func;
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s_func_arg[cpu_id] = arg;
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xTaskNotify(s_ipc_task_handle[cpu_id], wait_for, eSetValueWithOverwrite);
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xSemaphoreTake(s_ipc_ack[cpu_id], portMAX_DELAY);
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#ifdef CONFIG_ESP_IPC_USES_CALLERS_PRIORITY
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xSemaphoreGive(s_ipc_mutex[cpu_id]);
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#else
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xSemaphoreGive(s_ipc_mutex[0]);
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#endif
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return ESP_OK;
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}
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esp_err_t esp_ipc_call(uint32_t cpu_id, esp_ipc_func_t func, void* arg)
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{
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return esp_ipc_call_and_wait(cpu_id, func, arg, IPC_WAIT_FOR_START);
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}
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esp_err_t esp_ipc_call_blocking(uint32_t cpu_id, esp_ipc_func_t func, void* arg)
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{
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return esp_ipc_call_and_wait(cpu_id, func, arg, IPC_WAIT_FOR_END);
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}
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// currently this is only called from gcov component
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// the top level guarantees that the next call will be only after the previous one has completed
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#if CONFIG_APPTRACE_GCOV_ENABLE
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esp_err_t esp_ipc_start_gcov_from_isr(uint32_t cpu_id, esp_ipc_func_t func, void* arg)
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{
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if (xTaskGetSchedulerState() != taskSCHEDULER_RUNNING) {
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return ESP_ERR_INVALID_STATE;
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}
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// Since it is called from an interrupt, it can not wait for a mutex to be released.
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if (s_gcov_func == NULL) {
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s_gcov_func_arg = arg;
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s_gcov_func = func;
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// If the target task already has a notification pending then its notification value is not updated (WithoutOverwrite).
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xTaskNotifyFromISR(s_ipc_task_handle[cpu_id], IPC_WAIT_NO, eSetValueWithoutOverwrite, NULL);
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return ESP_OK;
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}
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// the previous call was not completed
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return ESP_FAIL;
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}
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#endif // CONFIG_APPTRACE_GCOV_ENABLE
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#endif // !defined(CONFIG_FREERTOS_UNICORE) || defined(CONFIG_APPTRACE_GCOV_ENABLE)
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